KR20010052419A - Combining sub-chip resolution samples in fingers of a spread-spectrum rake receiver - Google Patents

Abstract

A spread spectrum communication apparatus 1 comprising a channel estimator 11 and a rake receiver 10 having a plurality of rake fingers 20, 21, 22 of the present invention. The spread spectrum communication apparatus employs a code division multiple access system in direct sequence spread spectrum. In the spread spectrum system, the code is spread by a pseudo noise sequence at a chip rate greater than the code rate of the code. The spread code is modulated on the carrier, and the carrier modulated signal is transmitted over the propagation interface. The propagation interface generates a multipath component of the transmission signal. The spread spectrum communication device is demodulated by receiving a multipath component, despreading the received signal with a locally generated pseudo noise reference sequence, and coherently adding the intended multipath resolution component. After the carrier conveyance of the received signal, the spread spectrum communication device samples the demodulated signal at a sampling rate exceeding the chip rate to obtain a sample subchip resolution. Individual Rake fingers 20, 21, 22 coherently combine the resolved multipath components at subchip resolution, while each Rake finger processes multipath components separated by one or more chips. The rake receiver combines a subchip resolution multipath component coherently added to the individual rake fingers and a multipath component with one or more chips apart.

Description

Spread-Spectrum Communication Device and Receiving Method Using Them {COMBINING SUB-CHIP RESOLUTION SAMPLES IN FINGERS OF A SPREAD-SPECTRUM RAKE RECEIVER}

The so-called rake receiver of US Pat. No. 5,648, 983 has been disclosed for use in code division multiple access (CDMA) systems in direct sequential spread spectrum (DSSS), which in principle is a matched filter type digital code receiver, And a plurality of Rake fingers that correlate a delayed copy of the received signal with a reference sequence, such as a locally generated pseudo noise (PN) sequence. The received signal is a data signal and is despread in spectrum by the same pseudo noise sequence generated at the transmitter. The rake finger is coupled to a delayed line in which the delay between execution taps is less than the duration of the pseudo noise sequence element, which is the so-called chip. The output signals of the Rake fingers are combined to obtain a coherently added signal from a signal that propagates through the multipath channel and at the same time causes other propagation delays. The coherent addition signal dumps to the code detector at the speed of the code to be detected. In principle, the total delay of the tapped delay line is the delay spread order of the other propagation delays. A sampler provides a sample of the received signal to the tap delay line, and sampling is performed at a sub chip resolution, i.e. a sampling rate greater than the chip rate of the PN sequence. A channel evaluator coupled to the rake receiver actually resolves the multipath device closer to the chip reference by evaluating the channel impulse response at high resolution using a de-convolution technique. Before combining the output signal of the Rake finger, it is multiplied by an estimate of the signal phase for each path, which is obtained by a phase evaluator. Such a rake receiver can resolve multipath signals in which path elements are closer than one chip of the reference sequence, even at the expense of a sophisticated receiver structure with many rate fingers.

US Pat. No. 5,818,866, a method for use in a CDMA rake receiver, discloses a method for selecting a plurality of propagation delays to receive a message sent to a spread spectrum wireless communication system. The rake receiver includes a plurality of receive arms or fingers. Each finger serves to receive a signal along a propagation path identified by a particular delay, which delay is evaluated by the channel estimator. Each finger includes a correlator, a complex multiplier, and an add accumulator formed by a buffer memory, wherein the buffer memory stores a plurality of samples of the received signal and a buffer length of a plurality of samples corresponding to the maximum delay spread expected in the system. The size is memorable. In write mode, the buffer acts like a shift register, while in read mode the buffer is read at an address corresponding to the delay evaluated by the channel evaluator. The channel estimator includes a sliding correlator for determining the correlation between the received signal and the reference PN sequence. In the method, the received signal is sampled at a sampling rate greater than the chip rate of the spreading sequence so that the channel evaluator can evaluate the response magnitude of the propagation channel for the associated propagation delay at the subchip resolution. In the method, the delay for the finger is selected from the first and second lists. The first list includes a delay that corresponds to the center sample of the multipath correlation peak, while the second list includes a delay that corresponds to the neighbor sample of the center sample, which sample is above a predetermined selection threshold. Further, in the method, if the number of delays in the first list is greater than the number of arms of the rake receiver, the delay of the rake arms is selected from the first list having the largest evaluation energy. If a delay is set in the mode rake arm due to insufficient delay in the first list, an additional delay is selected from the second list in which the evaluation energy is above the selection threshold. In U. S. Patent No. 5, 648, 983, the so-called multipath diversity gain is obtained by interfering the output signal from the rake arm. In the method disclosed in US Pat. No. 5,818,866, the number of rake arms or fingers is constant and all arms are assigned a delay corresponding to a sample of the received signal with energy above the predetermined selection threshold.

The Rake receivers disclosed in U. S. Patent Nos. 5, 648, 983 and 5, 818, 866 are so-called baseband direct sequence spread spectrum receivers and are generally implemented in integrated circuits. In view of the cost of the view, it is desirable to keep the chip area of the IC as small as possible. Since the receiver is part of a portable communication transceiver provided by a battery, it is desirable for the receiver to reduce power consumption so that battery power is not consumed too quickly.

TIA / EIA Interim Standard {TIA / EIA / IS-95-A, May 1995, pages 6-7 to 6-11, 6-17, 6-18, 6-22 to 6-26, 7-1 to 7- 6, 7-16 to 7-20, and 7-22 to 7-24, the essential requirements for the operation of so-called IS-95 mobile stations and base stations are provided for transmitting and receiving CDMA direct sequential spread spectrum signals in the event of radio interference. do. On pages 6-7, an inverse CDMA channel is initiated during reception by the wireless base station, and an inverse CDMA channel structure is provided on pages 6-8 of Figures 6.1.3.1-2. On page 7-2 of Figure 7.1.3.1-1, the overall structure of the forward CDMA channel is provided for reception by the mobile base station. The reverse CDMA channel consists of an access channel and a reverse traffic channel, and all these channels share the same frequency radio channel using the CDMA direct sequence CDMA technique, and such radio channel has a bandwidth of 1.23 MHz. Each traffic channel is identified by the PN code sequence of each user. Data transmitted on the inverse CDMA channel is grouped into 20 ms frames. After conventional encoding and interleaving, all data on the inverse CDMA channel is modulated by 64 orthogonal modulation and orthogonal sequence spreading before transmission on the carrier. As shown in Fig. 6.1.3.1-2, orthogonal sequence spreading is done using a modulo 2 addition of Walsh chips and a user's long code sequence, wherein the orthogonal sequence spreading is performed using in-phase and square pseudo-noise sequences. After square spread, the square sequence is periodic with period 2 ¹⁵ . The spreading chip is filtered baseband before being modulated on the carrier. After interleaving, the code rate is constant in IS-95-A system 28, 800 sps. The six code codes are modulated with one of the 64 modulation systems for transmission. As described on pages 6-17, the modulation code is one of 64 mutually orthogonal waveforms generated using the so-called Walsh function. The PN chip rate is 1.2288 Mcps, with each Walsh chip spread by four pin chips. The long code is unique to the mobile station, while Walsh orthogonal modulation is applied to distinguish the CDMA channel transmitted at the provided radio frequency. In the forward CDMA channel structure, a CDMA code channel such as a pilot channel, a synchronization channel, a paging channel, and a plurality of forward traffic channels are formed, and the code channel is vertically spread by a suitable Walsh function, which has a constant chip rate of 1.2288 Mcps. Is performed after orthogonal sequential spreading using square pairs of PN sequences The spreading of the forward channel is done differently than in the reverse channel. Code channel zero is typically assigned to the pilot channel so that the pilot channel can be easily found, with 75 iterations of the pilot channel occurring every two seconds. The pilot channel is an unmodulated channel, distinguished by another timing offset within the master clock in the CDMA system. After baseband filtering on the forward and reverse channels, the square signal is mapped to the four phases of the carrier.

In the paper ["Digital Communications", JG Proakis, McGraw-Hill Book Company, 1989, pp. 862-872], time synchronization of a spread spectrum system is initiated, which is divided into two phases, and after signal timing The initial acquisition phase and the tracking phase are initially acquired. Time synchronization is so accurate that it is time synchronized within a small percentage of the chip spacing. On page 863, the sliding correlator is initiated to set up initial synchronization. The delay lock loop on page 867 of FIG. 8.5.5 is shown for PN sequence tracking, and such DLL tracking is described on pages 868 and 869.

The present invention relates to a code division multiple access system in which a code in a direct sequential spread spectrum is spread by a pseudo noise reference sequence at a chip rate greater than the code rate of the code to form a spread spectrum signal. Are modulated on a channel and simultaneously transmitted on an interface to generate a multipath component of the modulated spread spectrum signal.

The present invention also relates to a reception method for use in a direct sequential spread spectrum code division multiple access system.

1 is a block diagram of a spread spectrum communication device in accordance with the present invention.

2 is a block diagram of a rake receiver of a spread spectrum communication device in accordance with the present invention.

3 illustrates a rake finger of a rake receiver in accordance with the present invention.

4 illustrates a pseudo noise generator for use in a rake receiver in accordance with the present invention.

5 is a block diagram of a channel estimator using a spread spectrum communication apparatus in accordance with the present invention.

6 is a graphical representation of subchip resolution multipath components of a spread spectrum communications device according to the present invention;

7 illustrates a despreader for use in a spread spectrum communication device in accordance with the present invention.

8 illustrates a despreader for use in a spread spectrum communication device according to the present invention.

9 is a block diagram of a phase estimator for use with a rake finger of a rake receiver in accordance with the present invention.

It is an object of the present invention to provide a spread spectrum communication device in which the multipath components of a receive modulated spread spectrum signal at subchip resolution are efficiently combined and optimize the signal to noise ratio in the received signal.

It is another object of the present invention to provide a spread spectrum communication apparatus which saves power when a plurality of resolution multipath components at chip resolution are less than a plurality of rake fingers in a rake receiver consisting of the spread spectrum communication apparatus.

It is yet another object of the present invention to provide a spread spectrum communication device for selectively providing a subchip resolved multipath component to one finger of the rake receiver.

It is another object of the present invention to evaluate the average phase in the subchip resolution multipath component to be provided to one rake finger.

According to the present invention, a spread spectrum communication apparatus is used or provided in an orthogonal sequence code division multiple access system in which a code is spread by a pseudo noise reference sequence at a chip rate substantially larger than the code rate of the code to form a spread spectrum signal. The spread spectrum signal is modulated on a carrier and transmitted over jamming to generate a multipath component of the modulated spread spectrum signal. The spread spectrum communication device

Receiver front means for receiving the modulated spread spectrum signal;

Carrier demodulation means for demodulating the received modulated spread spectrum signal;

Sampler means for obtaining a sample from the demodulated spread spectrum signal and having a sampling rate exceeding the chip rate;

A channel estimator for evaluating from said sample of channel characteristics of said multipath component with sub-chip resolution and making a local maximum determination in said channel characteristics and for determining a sample position corresponding to said local maximum within a chip period;

A rake receiver coupled to the channel estimator, receiving the sample, the rake receiver having a plurality of receiver branches,

Each receiver branch

A down sampler for down sampling the sample based on the determined sample position;

Correlation means for correlating the down sampled sample with a locally generated pseudo noise reference sequence to generate a correlation value,

The rake receiver is

Combining means for weighting and combining the correlation values;

Determining means for determining a received sample value based on the weighted combined correlation value.

The rake receiver has less arms than known rake receivers because it combines the subchip resolution multipath components in one arm of the rake receiver at the same signal-to-noise ratio of the combined signal. When implementing the spread spectrum communication apparatus of the present invention in an integrated circuit, the size of the integrated circuit can be reduced. The integrated circuit can reduce manufacturing costs.

Preferably the power is switched off to the unused rake finger.

1 is a block diagram of a spread spectrum communication apparatus 1 according to the present invention. The spread spectrum communication device 1 is used in a direct sequential code division multiple access system, in which the code to be transmitted to the spread spectrum communication device 1 is substantially higher than the code rate of the code by a pseudo noise reference sequence. Spreads to form a spread spectrum signal. The spread spectrum signal is modulated on a carrier and transmitted on a propagating interface to generate a multipath component of the spread spectrum signal. Spread-spectrum signals are well known in the art. Known spread spectrum signals are narrowband spread spectrum systems as described in the TIA / EIA Interim standard (TIA / EIA / IS-95-A). Another spread spectrum system is the broadband spread spectrum currently standardized in various countries throughout the world. The spread spectrum communication device 1 receives a modulated spread spectrum signal [s (t)]. In the spread spectrum communication apparatus 1 according to the present invention, the received multipath component of the transmitted modulated spread spectrum signal s (t) is resolved at subchip resolution. The spread spectrum communication device 1 comprises a receiver front means 2 coupled to an antenna 3 for receiving the modulated spread spectrum signal [s (t)]. The front means 2 is a mixer 5 coupled to the front 4 for filtering and amplifying the received signal s (t) and a local oscillator 6 for demodulating the received signal s (t). Carrier demodulation means. In principle, although the spread spectrum communication device 1 is a non-directional device that receives only the signal s (t), the device 1 is typically a bidirectional communication device. The spread spectrum communication device 1 then further comprises a transmitter branch 7 in which the power amplifier 8 is shown. The transmitter branch 7 may be arranged to generate a spread spectrum signal as described in the TIA / EIA Interim standard (TIA / EIA / IS-95-A). The mixer 5 carries out demodulation spread spectrum signals in the form of square baseband signals [sI (t) and sQ9 (t)] from the signals [sI (t) and sQ9 (t)]. nTs) and sQ (nTs)], where t is time, n is an integer, and 1 / Ts is a sampling rate exceeding the chip rate of the received signal [s (t)]. The chip becomes the basic element of the pseudo noise sequence in which the code to be transmitted is spread. The spread spectrum device 1 can retrieve the sign or bit it intends by correlating the sample with a locally generated pseudo noise sequence identical to the pseudo noise reference sequence that transmitted the code. In order to perform the correlation and to combine the multipath components of the received modulated signal for which it is intended, the spectrum communication device 1 comprises a rake receiver 10 and a channel estimator 110. The channel estimator (11) evaluates the channel characteristics of the multipath component intended for it from the samples [sI (nTs) and sQ (nTs)] at subchip resolution and from the stream of samples [sI (nTs) and sQ (nTs)]. Provide information on the branch of the rake receiver 10 for any sample to be processed, which is indicated by bold arrows in Figure 1. The channel characteristic determines the local maximum of the correlation result and the corresponding sample position. The channel estimator 11 is represented as a correlation result within a chip period.The spread spectrum communication apparatus 1 includes a sign detector 12 and a rake receiver 10, the channel estimator 11 and a system detector 12. Coupled to It further comprises a processor (13).

2 is a block diagram of a rake receiver 10 in a spread spectrum communication device 1 according to the present invention. The rake receiver 10 includes a plurality of receiver branches, i.e. k rake fingers, where k is an integer. Rake fingers 20, 21 and 22 are shown. The output signals R1, R2, ..., Rk of each of the Rake fingers 1, 2, ... k are combiners combined by the diversity combiner 23 and form a multipath receive diversity combine signal S. do. The processor 13 can switch off power to the emergency rake finger by controlling power with the individual rake fingers to be switched off. At this end, the power supply control lines p1, p2 and p3 are provided. The bold arrow indicates information from the channel estimator 11 as described with respect to FIG. The information includes synchronization information for synchronizing a pseudo random sequence to be provided to the rake fingers 20, 21, and 22 with a pseudo random reference sequence implicitly indicated by the received signal s (t). In a spread spectrum system according to the TIA / EIA Interim standard (TIA / EIA / IS-95-A), a reference sequence repeating after 2 ¹⁵ chips determines synchronization.

3 shows a rake finger 20 of a rake receiver 10 according to the invention. The rake receiver 20 receives down sampling information (DSI) from the channel estimator 11 and instructs a down sampler to remove a sample from the input sample sequence si (nTs) and sQ (nTs). Down sampler 30 to select a multipath component with subchip resolution. The rake finger 20 includes a data despreader 31, a local pseudo noise reference generator 32, a phase estimator 33, and a reference combiner 34, the data despreader 33 and a phase estimator 34. The output of 33 is coherently coupled to the reference combiner 34. Such reference binding suggests that the subchip resolution multipath component is coupled to the rake finger 20 such that no harmful additives occur. In order to coherently combine the subchip resolution multipath components, the phase estimator 33 evaluates the combined phase of the subchip resolution multipath assigned to the rake finger 20.

4 shows the pseudo noise generator 32 for use in a rake finger of a rake receiver 10 in accordance with the present invention. The pseudo noise generator 32 comprises a pseudo noise code generator 40 for providing in-phase and square pseudo noise codes PN1 and PN _Q and a Walsh code generator 41 for providing a so-called Walsh code (WLS). . The pseudo noise generator 32 further comprises a dump signal DMP for controlling the reading of the data despreader 31 and the phase estimator 33. The pseudo noise generator 32 is synchronized by the channel estimator 11 to synchronize the locally generated pseudo noise reference sequence to a pseudo noise reference sequence for the rake receiver 10. The rake receiver 10 provided as an example may process signals generated in a narrowband DSSS CDMA system such as the IS-95-A system. In the IS-95-A system, the channel structure and spreading of the forward and reverse channels are very different. In the case of an IS-95-A system the present invention only provides a forward channel. Based on the synchronization information SY received from the channel estimator 11 at the rake receiver 10, the multipath may be resolved at the resolution of one or more chips. The pseudo noise generator 32 can be easily adapted to allow the rake receiver to process a wideband DSSS CDAM signal that is readily recognizable to those skilled in the art.

5 is a block diagram of a channel estimator 11 for use in the spread spectrum communication apparatus according to the present invention. The channel estimator 11 is similar to the despreader 50 and the PN code generator 40 shown in FIG. 4 so that only the received signal for the rake receiver produces a correlation peak at the output of the despreader 50. PN code generator 51 for controlling despreader 50. After despreading, the square despread signal of the received signal is integrated at each integrator 52 and 53, and the integral sample is squared at each square apparatus 54 and 55 and added to adder 56. The despread and sequentially added samples are stored in the amplitude table 57 at subchip resolution in the form of signal amplitude as a function of the phase of the PN code sequence. In the case of an IS-95-A system, the PN code phase is resolved at a resolution of 1 / (oversampling factor of 2 ¹⁵ times sampling means 9). The amplitude table 57 is coupled to an evaluation controller 58 that provides the synchronization information SY and down sampling information DSI. The evaluation controller 58 also controls the integration period of the integrators 52 and 53 by a control signal DMP that determines the phase of the PN code generator 51 and the dumping and resetting of the integrators 52 and 53. . The evaluation controller 58 controls the PN code generator 51 so that its amplitude table is constantly updated. The evaluation controller 11 analyzes an amplitude table 57 which retrieves a maximum in the subchip resolution and the resolution of one or more chips.

6 graphically illustrates a subchip resolution multipath component according to the present invention. The graph display shows the information stored in the amplitude table 57, and the amplitude AM of the despread, integrated and dumped samples is relative to the phase of the PN code generator 51 at the size of the original chip CP. Painted. As shown in Fig. 6, at a given point in time, the three maximums above the threshold TH are resolved at the received signal, i.e. one local maximum M1 and two local maximums M2 and M3 at subchip resolution. The maximum value M1 is spaced apart from the local maximum values M2 and M3 of one chip or more. The evaluation controller 58 controls the rake finger such that its maximum value M1 is processed by one rake finger and the maximum values M2 and M3 are processed by another rake finger. The maximum spaced apart from one or more chip periods is distinguished from the synchronization and information to be provided to the PN generator of the rake finger, while the local resolution in sub-chip resolution is distinguished by the down sampling information to be provided to the down sampler of the rake finger.

7 is an embodiment of a down sampler 30 for use in the rake finger 20 and other rake fingers 21 and 22 of the rake receiver 10 according to the present invention. The down sampler 30 receives a sample to be processed by receiving down sampling information (DSI) from the sampling means 9 from the input sample sequence [sI (nTs) and sQ (nTs)] and the channel evaluator 11. The down sampler 30 is instructed. The down sampler 30 includes a local table 70 that stores sample numbers to be processed, which are constantly updated by the channel estimator 11. The down sampler 30 also includes a modulo counter 71 and a comparator 72, which compares the output of the modulo counter 71 with a sample number entry of the local table 70. do. The comparator 72 controls the switch 73. The switch 73 is closed when the modulo counter value coincides with an entry in the local table 70, thereby taking the sample of the input data sequence si (nTs) and sQ (nTs) into the data despreader 31. And a phase evaluator 33. The modulo counter 71 periodically counts the number of samples per chip, i.e. sub-chip resolution.

8 shows a data despreader 31 for use in the spread spectrum communication device 1 according to the present invention. The data despreader 31 comprises a square signal despreader comprising a first multiplier 80, a first combiner 81, and an in-phase branch of the first integrator and dump device 82, and a second multiplier 83. A square branch comprising a second coupler 84 and a second integrating and dumping device 85. The data despreader 31 also includes a third multiplier 86 and a fourth multiplier 87, wherein the third multiplier includes an in-phase input 88 of the data despreader 31 and the second combiner ( 84 is coupled between the inputs 89 and the fourth multiplier 87 is cross coupled between the square input 90 of the data despreader 31 and the first combiner 81. The modulo 2 addition combination of the Walsh sequence WLS and the in-phase pseudo noise sequence PN ₁ , WLS + PN ₁ is provided to an input 92 of the first multiplier 80 and the Walsh sequence WLS And a modulo two summation of in-phase pseudo noise sequences [PN ₁ , WLS + (− PN ₁ )] is provided to the input 93 of the second multiplier 83, wherein the Walsh sequence and square pseudo noise are Modulo two addition combinations of the sequence [PN _Q , WLS + PN _Q ] are provided to inputs 94 and 95 of the third and fourth multipliers 86 and 87, where + is modulo two addition, i.e. exclusive. Indicates an OR operation. Although the despreader 50 of the channel estimator 11 shown in FIG. 5 has a similar structure, the Walsh code in the data despreader 31 is added to the PN code sequences PN ₁ and PN _Q in addition to the TIA / EIA. It is used to select code channels, such as the IS-95-A standard. The data multiplied by the despreader 31 is added over the sign period of the code to be detected by the sign detector 12. As a control signal (DMA),. The pseudo noise generator 31 signals the beginning and end of the code period.

9 is a block diagram of the phase estimator 33 used for the rake fingers of the rake receiver 10 according to the present invention. The phase estimator 33 includes a despreader 100 having a structure similar to the despreader 50, the outputs 101 and 102 of the despreader 100 being coupled to the low pass filters 103 and 104. Combined. At the outputs 105 and 106 of the low pass filters 103 and 104, phase estimation of data samples of in-phase and square branches can be used. The low pass filters 103 and 104 are used to reduce the noise of the evaluation signal by interpolating the despread signal at each output 101 and 102. Here, the despreading and filtering signals at the outputs 105 and 106 are added with the phase signal of the subchip resolution multipath component. As a result, Rake fingers that efficiently demodulate two or more subchip resolution multipath components add coherent evaluation of the multipath components.

Those skilled in the art will appreciate that various modifications and variations are possible without departing from the scope of the present invention. The word "comprising" does not exclude other components and steps of the claims.

Claims (10)

A code is used in an orthogonal sequence code division multiple access system in which a pseudo noise reference sequence is spread at a chip rate substantially larger than the code rate of the code to form a spread spectrum signal, and the spread spectrum signal is modulated and propagated on a carrier. A spread spectrum communication device (1), which generates a multipath component of the modulated spread spectrum signal by transmitting over an interface, Receiver front means (4) for receiving said modulated spread spectrum signal; Carrier demodulation means (5) for demodulating the received modulated spread spectrum signal; Sampling means 9 having samples [sI (nTs) and sQ (nTs)] from the demodulated spread spectrum signals si (t), sQ (t) and having a sample rate (1 / Ts) exceeding the chip rate; )and, Evaluate from the samples [sI (nTs) and sQ (nTs)] with subchip resolution of the channel characteristic of the multipath component and within the local maximums of the channel characteristic M1, M2, M3 and chip period cp A channel evaluator 11 for determining a sample position corresponding to a local maximum, A rake receiver coupled to the channel estimator 11, receiving the samples [sI (nTs) and sQ (nTs)], the rake receiver having a plurality of receiver branches, Each receiver branch 20, 21, 22 is A down sampler for sampling a sample down-sampled the samples [sI (nTs) and sQ (nTs)] based on the determined sample position; Correlation means for generating a correlation value (R1, R2, .... RK) in correlation with the down sampled sample and a locally generated pseudo noise reference sequence (PN ₁ , PN _Q , WLS) Including, The rake receiver 10 Coupling means 23 for weighting and combining the correlation values R1, R2, .... RK; Determining means (12) for determining a received sample value based on the weighted combined correlation value Containing more A spread spectrum communication device, characterized in that. The method of claim 1, A receiver branch 20, 21, 22 coupled to the channel estimator 11 to independently control the power of the receiver branches 20, 21, 22, wherein a local maximum is determined by the channel estimator 11. Spread spectrum communication device comprising a power supply control means (13) for switching off the power supply. The method of claim 1, The down sampler 30 Controllable switching means 73 coupled between the input of the receiver branch and the correlation means 31; Storage means 70 for storing a predetermined list of sample numbers received from the channel estimator 11, Modulo counter means 71 for a modulo for counting a plurality of samples per chip, Comparator means 72 coupled between the modulo counter means 71 and the storage means 70. Including; The comparator instructs the switching means 73 to close periodically when the count value of the counter means 71 matches the stored sample number A spread spectrum communication device, characterized in that. The method of claim 1, The receiver branch 20 includes a first despreader 31 and a multiplier 34, The first despreader 31 is coupled between the down sampler and the first input of the multiplier 34, and is coupled between the first despreader 31 and the second input of the multiplier 34. Further comprises a phase evaluator 33, The phase evaluator 33 is also coupled to the PN generator 32 included in the rake receiver 10, The PN generator 32 providing the local pseudo noise sequences PN ₁ , PN _Q , WLS A spread spectrum communication device, characterized in that. The method of claim 4, wherein Within the chip period cp, the phase estimator 33 determines the combined phase of the multipath component, The combined phase being used for reference combining the output signal of the receiver branches 20, 21, 22 A spread spectrum communication device, characterized in that. The method of claim 4, wherein The channel estimator (23) provides information to the PN generator (32) to select a multipath component having a resolution of one or more chip periods. The method of claim 4, wherein The phase evaluator 33 is A second despreader (100) providing a square component of said sample (sI (nTs) and sQ (nTs)), A first filter coupled to the first output 101 of the second despreader providing an in-phase phase estimate; A second filter 104 coupled to the second output of the second despreader 100 to provide a square phase estimate Including; The second despreader 100 having an input coupled to the in-phase and square outputs PN ₁ , PN _Q and a sign synchronization input DMP of the PN generator 32. A spread spectrum communication device, characterized in that. The method of claim 1. The channel estimator 11 derives synchronization information sy from the received spread spectrum signal s (t) and simultaneously synchronizes the local pseudo noise reference sequences PN ₁ , PN _Q , The synchronization information (sy) relates to multiple paths separated by one or more chip periods A spread spectrum communication device, characterized in that. The method of claim 4, wherein The first despreader 31 is an in-phase branch of the first multiplier 80, the first combiner 81, and the first integrating and dumping device 82, the second multiplier 83, and the second combiner 84. And a square despreader comprising a square branch including a second integrating and dumping device (85); A third multiplier 86 cross-coupled between an in-phase input 88 and an input 89 of the second combiner 84, A fourth coupler 87 cross coupled between the square input 90 of the despreader 31 and the input 91 of the first combiner 81, The modulo two summation of the Walsh sequence and the in-phase pseudo noise sequence (PN ₁ , WLS + PN ₁ ) is provided to an input 92 of the first multiplier 80, The modulo 2 addition combination of the Walsh sequence (WLS) and the in-phase pseudo noise sequence [PN ₁ , WLS + (− PN ₁ )] is provided to an input 93 of the second multiplier 83, The modulo two summation of the Walsh sequence (WLS) and the square pseudo noise sequence [PN _Q , WLS + PN _Q ] is provided to inputs 94 and 95 of the third and fourth multipliers 86 and 87. A spread spectrum communication device, characterized in that. A code is used in an orthogonal sequence code division multiple access system in which a pseudo noise reference sequence is spread at a chip rate substantially larger than the code rate of the code to form a spread spectrum signal, and the spread spectrum signal is modulated and propagated on a carrier. A reception method using a code division multiple access system in a direct sequence spread spectrum which generates a multipath component of the modulated spread spectrum signal by transmitting across an interface, Receiving the modulated spread spectrum signal [s (t)]; Demodulating the received modulated spread spectrum signal; Sampling the demodulated spread spectrum signals [sI (t), sQ (t)] at a sampling rate (1 / Ts) exceeding the chip rate to obtain samples [sI (nTs) and sQ (nTs)]; Evaluate from the samples [sI (nTs) and sQ (nTs)] with subchip resolution of the channel characteristic of the multipath component and within the local maximums of the channel characteristic M1, M2, M3 and chip period cp Determining a sample location corresponding to a local maximum, Downsampling the samples [sI (nTs) and sQ (nTs)] based on the determined sample positions; Generating a correlation value (R1, R2, .... RK) in correlation with the down sampled sample and a locally generated pseudo noise reference sequence (PN ₁ , PN _Q , WLS), Weighting and combining the correlation values (R1, R2, .... RK), And further comprising determining means (12) for determining a received sample value based on the weighted combined correlation value. Receiving method characterized in that.